Method and system for inspecting indirect bandgap semiconductor structure

1. A method of analyzing an indirect bandgap semiconductor material, said method comprising the steps of: generating substantially monochromatic light suitable for inducing photoluminescence in said indirect bandgap semiconductor material; short-pass filtering said substantially monochromatic light to reduce long-wavelength light of said generated light above a predetermined emission peak; collimating said substantially monochromatic light; illuminating said indirect bandgap semiconductor material with said collimated, short-pass filtered substantially monochromatic light to induce a measurable photoluminescence signal from said indirect bandgap semiconductor material; and capturing, with an image capture device, an image of photoluminescence of the indirect bandgap semiconductor material, from which information on one or more material properties of said indirect bandgap semiconductor material can be obtained, induced in a large area of said indirect bandgap semiconductor material by the illumination, wherein said material properties are at least one of shunts, current-voltage characteristics, diffusion lengths and minority carrier lifetimes.

2. A method as claimed in claim 1 , further comprising a step of processing said image to determine spatial variations of luminescence in said image.

3. A method as claimed in claim 2 , wherein said processing of said image comprises determining spatial variations of said one or more material properties of said indirect bandgap semiconductor material using spatial variations in said image.

4. A method as claimed in claim 2 , wherein said processing step is effected within about 1 second.

5. A method as claimed in claim 2 , wherein any one of said illuminating, capturing and processing steps is conducted in-line on a production process.

6. A method as claimed in claim 1 , wherein said illumination is substantially homogeneous across said area.

7. A method as claimed in claim 1 , wherein said short-pass filtering substantially removes components in a wavelength range of said photoluminescence.

8. A method as claimed in claim 1 , wherein light incident on said image capture device is long pass filtered to substantially prevent said illumination from being imaged.

9. A method as claimed in claim 1 , wherein said illumination is applied to one side of said indirect bandgap semiconductor material, and wherein said image capture device captures photoluminescence emitted from an opposite side of said indirect bandgap semiconductor material that is generated by said illumination of said one side, such that said indirect bandgap semiconductor material serves as a long pass filter to substantially prevent said illumination from being imaged.

10. A method as claimed in claim 1 , wherein said illuminating of said indirect bandgap semiconductor material is performed for up to 1 second.

11. A method as claimed in claim 1 , wherein said illuminating and capturing steps are effected within about 1 second.

12. A method as claimed in claim 1 , wherein the method is applied to an indirect bandgap semiconductor material selected from the group consisting of: a silicon structure, a bare or partially processed wafer, a bare or partially processed Silicon-On-Insulator (SOI) structure, a fully fabricated silicon device and a solar cell.

13. A method as claimed in claim 1 , wherein said area is at least 1 cm 2 .

14. A method as claimed in claim 1 , wherein said area comprises an entire side of said indirect bandgap semiconductor material.

15. A method as claimed in claim 1 , wherein at least said illuminating and capturing steps are performed while said indirect bandgap semiconductor material is at room temperature.

16. In a multi-step process for producing semiconductor devices from an indirect bandgap semiconductor material, a method of analyzing one or more material properties of said indirect bandgap semiconductor material, said method comprising the steps of: generating substantially monochromatic light suitable for inducing photoluminescence in said indirect bandgap semiconductor material; short-pass filtering said substantially monochromatic light to reduce long-wavelength light of said generated light above a predetermined emission peak; collimating said substantially monochromatic light; illuminating said indirect bandgap semiconductor material with said collimated, short-pass filtered substantially monochromatic light to induce a measurable photoluminescence signal from said indirect bandgap semiconductor material; and capturing an image of photoluminescence of the indirect bandgap semiconductor material, from which information on said one or more material properties can be obtained, induced in a large area of said indirect bandgap semiconductor material by the illumination; and processing spatial variations in said image to determine spatial variations of said one or more material properties, wherein said illuminating, capturing and processing steps are conducted within a predetermined production step of said process, and wherein said material properties are at least one of shunts, current-voltage characteristics, diffusion lengths and minority carrier lifetimes.

17. A method for analyzing one or more material properties of an indirect bandgap semiconductor material in a process for producing a semiconductor device from said indirect bandgap semiconductor material, said method comprising the steps of: generating substantially monochromatic light suitable for inducing photoluminescence in said indirect bandgap semiconductor material; short-pass filtering said substantially monochromatic light to reduce long-wavelength light of said generated light above a predetermined emission peak; collimating said substantially monochromatic light; illuminating said indirect bandgap semiconductor material with said collimated, short-pass filtered substantially monochromatic light to induce a measurable photoluminescence signal from said indirect bandgap semiconductor material; and capturing an image of photoluminescence of the indirect bandgap semiconductor material, from which information on said one or more material properties can be obtained, induced in a large area of said indirect bandgap semiconductor material by the illumination; and processing said image to determine spatial variations of said one or more material properties, wherein said method is applied to said indirect bandgap semiconductor material at any point between said indirect bandgap semiconductor material being a bare wafer and a completed device, and wherein said material properties are at least one of shunts, current-voltage characteristics, diffusion lengths and minority carrier lifetimes.

18. A system for analyzing an indirect bandgap semiconductor material, said system comprising: a light source generating substantially monochromatic light for illuminating said indirect bandgap semiconductor material with light suitable for inducing photoluminescence from said indirect bandgap semiconductor material; a short-pass filter that reduces long-wavelength light of said substantially monochromatic light above a predetermined emission peak; a collimator for collimating said substantially monochromatic light; wherein said collimated, short-pass filtered substantially monochromatic light illuminates said indirect bandgap semiconductor material for inducing a measurable photoluminescence signal from said indirect bandgap semiconductor material; and an image capture device for capturing an image of photoluminescence of the indirect bandgap semiconductor material, from which information on one or more material properties of said indirect bandgap semiconductor material can be obtained, induced in a large area of said indirect bandgap semiconductor material by the illumination, wherein said material properties are at least one of shunts, current-voltage characteristics, diffusion lengths and minority carrier lifetimes.

19. A system as claimed in claim 18 , further comprising a processor configured to determine spatial variations of luminescence in said image.

20. A system as claimed in claim 19 , wherein said processor is configured to determine spatial variations of said one or more material properties of said indirect bandgap semiconductor material using spatial variations in said image.

21. A system as claimed in claim 18 , wherein said system is configured to illuminate said area substantially homogeneously.

22. A system as claimed in claim 18 , wherein said short pass filter is disposed between said light source and said indirect bandgap semiconductor material, for substantially removing components of said illumination in a wavelength range of said photoluminescence.

23. A system as claimed in claim 18 , further comprising a long pass filter disposed between said indirect bandgap semiconductor material and said image capture device substantially preventing said substantially monochromatic light from reaching said image capture device.

24. A system as claimed in claim 18 , wherein said light source illuminates one side of said indirect bandgap semiconductor material, wherein said image capture device captures photoluminescence emitted from an opposite side of said indirect bandgap semiconductor material that is generated by said illumination of said one side, and wherein said indirect bandgap semiconductor material substantially prevents said substantially monochromatic light from reaching said image capture device.

25. A system as claimed in claim 18 , wherein said system is adapted to illuminate said area for about 1 second or less.

26. A system as claimed in claim 18 , wherein said light source and said image capture device are adapted to illuminate said indirect bandgap semiconductor material and capture said image within about 1 second.

27. A system as claimed in claim 18 , wherein said system is located in-line on a production process.

28. A system as claimed in claim 18 , wherein said system is adapted to analyze an indirect bandgap semiconductor material selected from the group consisting of: silicon, a bare or partially processed wafer, a bare or partially processed Silicon-On-Insulator (SOI) structure, a fully fabricated silicon device and a solar cell.

29. A system as claimed in claim 18 , wherein said system is adapted to capture an image of photoluminescence induced in at least 1 cm 2 of said indirect bandgap semiconductor material.

30. A system as claimed in claim 18 , wherein said system is adapted to capture an image of photoluminescence induced in the entire area of one side of said indirect bandgap semiconductor material.

31. In a multi-step process for producing semiconductor devices from an indirect bandgap semiconductor material, a system for analyzing one or more material properties of said indirect bandgap semiconductor material, said system comprising: a light source generating substantially monochromatic light for illuminating said indirect bandgap semiconductor material with light suitable for inducing photoluminescence from said indirect bandgap semiconductor material; a short-pass filter that reduces long-wavelength light of said substantially monochromatic light above a predetermined emission peak; a collimator for collimating said substantially monochromatic light; wherein said collimated, short-pass filtered substantially monochromatic light illuminates said indirect bandgap semiconductor material for inducing a measurable photoluminescence signal from said indirect bandgap semiconductor material; and an image capture device for capturing an image of photoluminescence of the indirect bandgap semiconductor material, from which information on said one or more material properties can be obtained, induced in a large area of said indirect bandgap semiconductor material by the illumination; and a processor for processing spatial variations in said image to determine spatial variations of said one or more material properties, wherein said material properties are at least one of shunts, current-voltage characteristics, diffusion lengths and minority carrier lifetimes.

32. A multi-step process line for producing an indirect bandgap semiconductor device, said process line comprising one or more systems according to claim 31 located at one or more positions in said process line.